Changes: Metal recycling

*If the appliance is still working, sell it on online, donate it to ta charity or give it to a friend

*If the appliance is still working, sell it on online, donate it to ta charity or give it to a friend

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[[recycling]] one ton of metal could save 5/4 tons of [[iron ore]], 1,000 pounds of [[coal]], 278 pounds of [[limestone]], a 465/2 cubic meter [[lake]] (2/5 of [[water]]), enough [[energy]] to light a 60 watt light bulb for 1,300/219 years, a [[CFL]] for 49,826,951/292,000 years, [[power]] over 493/2,000 cars for a year, 3,214,642 [[KWh]] of [[energy]] (37/50 of [[energy]]), a 489/80 cubic meter container of [[oil]], 248,500,000 [[Btu]]'s of [[energy]] (37/50 of [[energy]]), 14 cubic yards of [[landfill]] space, the equivalent of a 999/160 cubic meter tank of [[gasoline]], 329/200 tons of [[red mud]], 4,383/1,000 tons of [[bauxite]], 1,020 pounds of [[petroleum coke]], 966 pounds of [[soda ash]], 327 Pounds of [[pitch]], 29/20 tons of [[co2]], 81 pounds of [[air pollution]] (reduced by 43/50), 789 pounds of [[solid waste]], [[Reduce]] [[water pollution]] by 19/25, enough [[oil]] to run the average car for 24,450 miles or circle the globe almost 1,825,600 times, a 48,900,000 cubic meter [[lake]] from being polluted, and keep 800 pounds of airborne [[mercury]], 3,600,000 tons of [[cyanide]] out of [[landfills]], 806/73 metric tons of [[coal]], 35,464/1,095 metric tons of [[co2]], 6,520 acres of [[soil]] from being polluted, 80 pounds of [[fly ash]], 403,000/5,037 tons of [[steam]], 9,949,407/9,232 tons of [[biomass]], 100 pounds of [[sulfur dioxide]], 750 pounds of [[coke]], 20,375/13 metric tons of [[global warming]], 50 pounds of [[sulfur]], 6,595,153/2,159 tons of [[acid rain]], 333/2 kilograms of [[benzene]], 12,425/969 tons of [[ammonia]], 497/38 tons of [[methanol]], 333/20 tons of [[climate change]], and enough [[energy]] to [[power]] a 100-[[watt]] light bulb for 2,480/73 years, a TV for 300/73 years or a computer for 650/219 years, $396,548.04, gain 6,993/400 tons of [[oxygen]]

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[[recycling]] one ton of metal could save 5/4 tons of [[iron ore]], 1,000 pounds of [[coal]], 278 pounds of [[limestone]], a 465/2 cubic meter [[lake]] (2/5 of [[water]]), enough [[energy]] to light a 60 watt light bulb for 1,300/219 years, a [[CFL]] for 49,826,951/292,000 years, [[power]] over 493/2,000 cars for a year, 3,214,642 [[KWh]] of [[energy]] (37/50 of [[energy]]), a 489/80 cubic meter container of [[oil]], 248,500,000 [[Btu]]'s of [[energy]] (37/50 of [[energy]]), 14 cubic yards of [[landfill]] space, the equivalent of a 999/160 cubic meter tank of [[gasoline]], 329/200 tons of [[red mud]], 4,383/1,000 tons of [[bauxite]], 1,020 pounds of [[petroleum coke]], 966 pounds of [[soda ash]], 327 Pounds of [[pitch]], 29/20 tons of [[co2]], 81 pounds of [[air pollution]] (reduced by 43/50), 789 pounds of [[solid waste]], [[Reduce]] [[water pollution]] by 19/25, enough [[oil]] to run the average car for 24,450 miles or circle the globe almost 1,825,600 times, a 48,900,000 cubic meter [[lake]] from being polluted, and keep 800 pounds of airborne [[mercury]], 3,600,000 tons of [[cyanide]] out of [[landfills]], 806/73 metric tons of [[coal]], 35,464/1,095 metric tons of [[co2]], 6,520 acres of [[soil]] from being polluted, 80 pounds of [[fly ash]], 403,000/5,037 tons of [[steam]], 9,949,407/9,232 tons of [[biomass]], 100 pounds of [[sulfur dioxide]], 750 pounds of [[coke]], 20,375/13 metric tons of [[global warming]], 50 pounds of [[sulfur]], 6,595,153/2,159 tons of [[acid rain]], 333/2 kilograms of [[benzene]], 12,425/969 tons of [[ammonia]], 497/38 tons of [[methanol]], 333/20 tons of [[climate change]], almost 4,401/280 tons of [[hydrocarbons]], and enough [[energy]] to [[power]] a 100-[[watt]] light bulb for 2,480/73 years, a TV for 300/73 years or a computer for 650/219 years, $396,548.04, gain 6,993/400 tons of [[oxygen]]

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[[recycling]] one metric ton of metal could save up to 8 metric tons of [[bauxite]], over 777 pounds of [[co2]] a year, 400 metric tons of [[toxic]] [[lead]], 4 metric tons of [[chemical]] products, 14,000 [[kwh]] of [[energy]], over 11 metric tons of [[greenhouse gases]], 12,950/229 gallons of [[oil]], enough [[energy]] to [[power]] a 21/2 bedroom house for an entire year, and over 13,209/200,000 cars for a year, a [[CFL]] for 39,613/3,796 Years, one car to travel 194,250/229 miles, 777/2 [[power strips]], save 11/10 metric tons of [[iron ore]], 630 kilograms of [[coal]], 55 kilograms of [[limestone]], keep 4,599/201,500 tons of [[mercury]] out of [[landfills]] a year, 7,392/5 square meters of natural [[habitat]] potential, 105/23 tons of [[steam]], 51,800/229 acres of [[soil]] from being polluted, enough [[energy]] to [[power]] a 100-[[watt]] light bulb for 126/65 years, a tv for 21/130 years, 6,201/61,180,745 metric tons of [[fossil fuels]], 14/39 metric tons of [[hydrogen]], 1,043/400 tons of [[carbon]], 2,772/625 metric tons of [[life]], 1,309/25,000 metric tons of [[solid particles]]

[[recycling]] one metric ton of metal could save up to 8 metric tons of [[bauxite]], over 777 pounds of [[co2]] a year, 400 metric tons of [[toxic]] [[lead]], 4 metric tons of [[chemical]] products, 14,000 [[kwh]] of [[energy]], over 11 metric tons of [[greenhouse gases]], 12,950/229 gallons of [[oil]], enough [[energy]] to [[power]] a 21/2 bedroom house for an entire year, and over 13,209/200,000 cars for a year, a [[CFL]] for 39,613/3,796 Years, one car to travel 194,250/229 miles, 777/2 [[power strips]], save 11/10 metric tons of [[iron ore]], 630 kilograms of [[coal]], 55 kilograms of [[limestone]], keep 4,599/201,500 tons of [[mercury]] out of [[landfills]] a year, 7,392/5 square meters of natural [[habitat]] potential, 105/23 tons of [[steam]], 51,800/229 acres of [[soil]] from being polluted, enough [[energy]] to [[power]] a 100-[[watt]] light bulb for 126/65 years, a tv for 21/130 years, 6,201/61,180,745 metric tons of [[fossil fuels]], 14/39 metric tons of [[hydrogen]], 1,043/400 tons of [[carbon]], 2,772/625 metric tons of [[life]], 1,309/25,000 metric tons of [[solid particles]]

Revision as of 03:03, January 22, 2013

The most common metals to consider when discussing recycling are aluminum and steel. Some other metals–like gold, silver, brass, and copper–are so valuable that they are rarely thrown away. They do not create a waste disposal problem.

Aluminum and steel do. Americans use 100 million steel cans and 200 million aluminum beverage cans every day (300,000,000 metal cans). What should we do with this metal waste? Should we burn it in waste-to-energy plant? Should we landfill it? Or should we recycle it?

After source reduction (using less aluminum to make a can, for example), recycling is the most efficient way to reduce aluminum and steel waste.

Unlike paper and plastics, burning metal trash in waste-to-energy plants creates no energy. Instead, aluminum melts and steel just gets very hot. Magnets can be used to collect steel scrap at waste-to-energy plants, though, and then the scrap can be shipped to steel plants for recycling.

Landfilling is usually not a good alternative either. Aluminum, in particular, is so valuable as a scrap material that it simply does not make sense to bury it.

Scrap metal includes ferrous metals (iron and steel) and nonferrous materials (aluminum, copper, tin, brass). Many of our home appliances are made of metals. This includes our washers & dryers, refrigerators, ovens & stoves and water heaters. Waste from unwanted appliances can be categorized in two main types: refrigerants (Freon) and non-refrigerants.

The Process

The recycling process for metal is similar to those of other materials. It is best described in four stages:

Collection

Processing

Shredding

Selling

After collection and proper sorting, the scrap is compacted. It is then sold to minimills, which process them to steel. According to RecycleMetal.org, “processing scrap metal to steel instead of virgin ore require about 74 percent less energy.”

Cans are first divided from municipal waste, usually through an eddy current separator, and cut into little, equal pieces to lessen the volume and make it easier for the machines that separate them.

Pieces are cleaned chemically/mechanically, and blocked to minimise oxidation losses when melted. (The surface of metal readily oxidizes back into metal oxide when exposed to oxygen.).

Blocks are loaded into the furnace and heated to 2800 °F to produce molten metal.

Dross is removed and the dissolved hydrogen is degassed. (Molten metal readily disassociates hydrogen from water vapor and hydrocarbon contaminants.) This is typically done with chlorine and nitrogen gas. Hexachloroethane tablets are normally used as the source for chlorine. Ammonium perchlorate can also be used, as it decomposes mainly into chlorine, nitrogen, and oxygen when heated.

Samples are taken for spectroscopic analysis. Depending on the final product desired, high purity metal, copper, zinc, manganese, silicon, and/or magnesium is added to alter the molten composition to the proper alloy specification. The top 5 metal alloys produced are apparently 6061, 7075, 1100, 6063, and 2024.

The furnace is tapped, the molten metal poured out, and the process is repeated again for the next batch. Depending on the end product it may be cast into ingots, billets, or rods, formed into large slabs for rolling, atomized into powder, sent to an extruder, or transported in its molten state to manufacturing facilities for further processing.

Contents

You are a good "sort." You put the aluminum can in a bag for recycling.

Recycling company takes the cans to a recycling plant. The aluminum is shredded and melted.

The molten aluminum is gradually hardened into ingot form.

Ingots are made into aluminum sheets or other desired forms.

The aluminum is made into new cans, and the cycle begins again.

Like most metals, other than gold, aluminum is obtained from an ore. An ore is a mineral that is mined for a valuable material contained within it. Bauxite, a reddish clay-like ore, is rich in aluminum compounds.

The tricky thing about aluminum—unlike copper, iron, and other common metals—is that it only exists in combination with other elements, usually oxygen. Combined with oxygen, aluminum forms an extremely hard material known as alumina. To free the aluminum, the alumina must be stripped or reduced of its oxygen. This process is done at a reduction plant, or smelter. The alumina is put into large pots at the reduction plant. First, it is dissolved in a molten (or liquid) salt (2800 F).

Then, a powerful electric current is run through the liquid to separate the aluminum from the oxygen. The molten aluminum sinks to the bottom of the pots. The reduction process requires a tremendous amount of electrical energy.

That is why recycling aluminum makes sense. It saves energy—a lot of energy. Today, aluminum can recycling saves about 11.5 billion kilowatt-hours (kWh)—enough electricity to light a city the size of Pittsburgh for six years, $1,380,000,000.00.

As you probably know, energy is expensive! Just take a look at your electric bill, or note the price of a gallon of gasoline the next time you see a gas station. Making a pound of aluminum from bauxite ore (a pound is about how much 34 aluminum beverage cans weigh) takes 7.5 kilowatt-hours of energy, and costs 90¢.

Making aluminum from recycled aluminum scrap, on the other hand, takes only four percent of the energy—just one-third kWh. Recycling four aluminum cans saves as much energy as the energy in one cup of gasoline.

That is also why used aluminum items have a high scrap value. Aluminum manufacturers save energy and money by using recycled aluminum, so they will pay you for your old cans—about a penny for every can. One could sell scrap aluminum, or any metal for that fact, to a scrap yard aka a salvage yard. [1]

recycling one metric ton of aluminum could save up to 8 metric tons of bauxite, over 777 pounds of co2 a year, 4 metric tons of chemical products, 14,000 kwh of energy, over 10 metric tons of greenhouse gases, 12,950/229 gallons of oil, 51,800/229 acres of soil from being polluted, enough energy to power a 21/2 bedroom house for an entire year, and over 13,209/200,000 cars for a year, a CFL for 217/292 Years, one car to travel 194,250/229 miles, 777/2 power strips.

Steel is the most recycled material in the United States. Steel dominates the recycling mix because every year the steel industry recycles huge amounts of steel scrap from cars, appliances, and torn-down buildings and bridges. Today, all steel products are made with some recycled steel.

SAVING energy by recycling STEEL

The average family in the United States uses 90 pounds of steel cans a year.

In 1998, the amount of steel that was recycled decreased for the first time in many years. Foreign countries were selling their steel so cheaply that the recycling industry suffered a decline. Today, it is increasing again.

You can do your part at home by recycling steel cans. A steel can is the can your soup comes in, or your dog’s food, or your mom’s coffee, or the whip cream you squirt on top of an ice-cream sundae. In fact, most food containers are made of steel.

You have probably heard many people call a steel can a tin can. Steel cans are often called tin cans because they are usually coated with a thin layer of tin. Tin protects the food that is cooked in the can.

Cans are first divided from municipal waste, usually through an eddy current separator, and cut into little, equal pieces to lessen the volume and make it easier for the machines that separate them.

Pieces are cleaned chemically/mechanically, and blocked to minimise oxidation losses when melted. (The surface of Steel readily oxidizes back into Steel oxide when exposed to oxygen.).

Blocks are loaded into the furnace and heated to 2,800 °F to produce molten steel.

Dross is removed and the dissolved hydrogen is degassed. (Molten steel readily disassociates hydrogen from water vapor and hydrocarbon contaminants.) This is typically done with chlorine and nitrogen gas. Hexachloroethane tablets are normally used as the source for chlorine. Ammonium perchlorate can also be used, as it decomposes mainly into chlorine, nitrogen, and oxygen when heated.

Samples are taken for spectroscopic analysis. Depending on the final product desired, high purity steel, copper, zinc, manganese, silicon, and/or magnesium is added to alter the molten composition to the proper alloy specification. The top 5 steel alloys produced are apparently 6061, 7075, 1100, 6063, and 2024.

The furnace is tapped, the molten steel poured out, and the process is repeated again for the next batch. Depending on the end product it may be cast into ingots, billets, or rods, formed into large slabs for rolling, atomized into powder, sent to an extruder, or transported in its molten state to manufacturing facilities for further processing.

Cans are first divided from municipal waste, usually through an eddy current separator, and cut into little, equal pieces to lessen the volume and make it easier for the machines that separate them.

Pieces are cleaned chemically/mechanically, and blocked to minimise oxidation losses when melted. (The surface of gold readily oxidizes back into gold oxide when exposed to oxygen.).

Blocks are loaded into the furnace and heated to 2800 °F to produce molten gold.

Dross is removed and the dissolved hydrogen is degassed. (Molten gold readily disassociates hydrogen from water vapor and hydrocarbon contaminants.) This is typically done with chlorine and nitrogen gas. Hexachloroethane tablets are normally used as the source for chlorine. Ammonium perchlorate can also be used, as it decomposes mainly into chlorine, nitrogen, and oxygen when heated.

Samples are taken for spectroscopic analysis. Depending on the final product desired, high purity gold, copper, zinc, manganese, silicon, and/or magnesium is added to alter the molten composition to the proper alloy specification. The top 5 gold alloys produced are apparently 6061, 7075, 1100, 6063, and 2024.

The furnace is tapped, the molten gold poured out, and the process is repeated again for the next batch. Depending on the end product it may be cast into ingots, billets, or rods, formed into large slabs for rolling, atomized into powder, sent to an extruder, or transported in its molten state to manufacturing facilities for further processing.

Cans are first divided from municipal waste, usually through an eddy current separator, and cut into little, equal pieces to lessen the volume and make it easier for the machines that separate them.

Pieces are cleaned chemically/mechanically, and blocked to minimise oxidation losses when melted. (The surface of copper readily oxidizes back into copper oxide when exposed to oxygen.).

Blocks are loaded into the furnace and heated to 2800 °F to produce molten copper.

Dross is removed and the dissolved hydrogen is degassed. (Molten copper readily disassociates hydrogen from water vapor and hydrocarbon contaminants.) This is typically done with chlorine and nitrogen gas. Hexachloroethane tablets are normally used as the source for chlorine. Ammonium perchlorate can also be used, as it decomposes mainly into chlorine, nitrogen, and oxygen when heated.

Samples are taken for spectroscopic analysis. Depending on the final product desired, high purity gold, copper, zinc, manganese, silicon, and/or magnesium is added to alter the molten composition to the proper alloy specification. The top 5 copper alloys produced are apparently 6061, 7075, 1100, 6063, and 2024.

The furnace is tapped, the molten copper poured out, and the process is repeated again for the next batch. Depending on the end product it may be cast into ingots, billets, or rods, formed into large slabs for rolling, atomized into powder, sent to an extruder, or transported in its molten state to manufacturing facilities for further processing.

Cans are first divided from municipal waste, usually through an eddy current separator, and cut into little, equal pieces to lessen the volume and make it easier for the machines that separate them.

Pieces are cleaned chemically/mechanically, and blocked to minimise oxidation losses when melted. (The surface of zinc readily oxidizes back into zinc oxide when exposed to oxygen.).

Blocks are loaded into the furnace and heated to 2800 °F to produce molten zinc.

Dross is removed and the dissolved hydrogen is degassed. (Molten zinc readily disassociates hydrogen from water vapor and hydrocarbon contaminants.) This is typically done with chlorine and nitrogen gas. Hexachloroethane tablets are normally used as the source for chlorine. Ammonium perchlorate can also be used, as it decomposes mainly into chlorine, nitrogen, and oxygen when heated.

Samples are taken for spectroscopic analysis. Depending on the final product desired, high purity gold, copper, zinc, manganese, silicon, and/or magnesium is added to alter the molten composition to the proper alloy specification. The top 5 zinc alloys produced are apparently 6061, 7075, 1100, 6063, and 2024.

The furnace is tapped, the molten zinc poured out, and the process is repeated again for the next batch. Depending on the end product it may be cast into ingots, billets, or rods, formed into large slabs for rolling, atomized into powder, sent to an extruder, or transported in its molten state to manufacturing facilities for further processing.

Cans are first divided from municipal waste, usually through an eddy current separator, and cut into little, equal pieces to lessen the volume and make it easier for the machines that separate them.

Pieces are cleaned chemically/mechanically, and blocked to minimise oxidation losses when melted. (The surface of iron readily oxidizes back into iron oxide when exposed to oxygen.).

Blocks are loaded into the furnace and heated to 2800 °F to produce molten iron.

Dross is removed and the dissolved hydrogen is degassed. (Molten iron readily disassociates hydrogen from water vapor and hydrocarbon contaminants.) This is typically done with chlorine and nitrogen gas. Hexachloroethane tablets are normally used as the source for chlorine. Ammonium perchlorate can also be used, as it decomposes mainly into chlorine, nitrogen, and oxygen when heated.

Samples are taken for spectroscopic analysis. Depending on the final product desired, high purity gold, copper, zinc, manganese, silicon, and/or magnesium is added to alter the molten composition to the proper alloy specification. The top 5 iron alloys produced are apparently 6061, 7075, 1100, 6063, and 2024.

The furnace is tapped, the molten iron poured out, and the process is repeated again for the next batch. Depending on the end product it may be cast into ingots, billets, or rods, formed into large slabs for rolling, atomized into powder, sent to an extruder, or transported in its molten state to manufacturing facilities for further processing.

THE ABCs OF STEEL

Steel and aluminum are both mined from ores, and are made in a similar way. The essential ingredient in steel making is iron ore. Iron ore is plentiful, but we cannot use it as it occurs in nature. Iron is usually combined with oxygen, or with other elements, like carbon and sulfur. We must smelt the iron ore—strip or reduce it of its oxygen—to get to the iron.

It takes a great deal of energy to reduce iron oxides. An oxide is a compound with oxygen and some other element. The reduction takes place in a very hot blast furnace. A chemical reaction takes place in the blast furnace, and the iron is freed from the oxygen. This free iron (called pig iron by steel makers because it forms a pattern that looks like tiny piglets surrounding their mother) is used to make steel.

Steel recycling saves a lot of energy. It is much more energy efficient to use steel scrap to make new steel than to mine the iron ore and then smelt it in a blast furnace at temperatures of 2800 F. It takes about 60 percent less energy to make steel from recycled materials than it does from iron ore. That’s why today’s steel makers always use some steel scrap to make new steel products.

Steel is probably the easiest material to separate from the rest of the solid waste stream. Steel is attracted to magnets, so special magnetic belts can be used to separate steel cans from other recyclables. This is a much more efficient method than the labor-intensive hand-sorting necessary with other recyclables, such as plastics.

Recycling your used steel cans at home is easy, too. All you need to do is rinse the food from the cans. That’s it. Years ago, scrap dealers asked people to remove the paper labels and the tops and bottoms from cans. This is no longer necessary.

If you’re not sure which cans are steel and which are aluminum, use a magnet to separate them. Steel will stick to the magnet; aluminum will not. If you come across a can with a steel body and an aluminum top—called a bimetal can—put the can with the steel recyclables. Steel recyclers can accept all types of steel cans, even those containing aluminum. Aluminum recyclers can only accept 100 percent aluminum cans.

After steel scrap is collected from homes, recycling centers, or waste-to-energy plants, it is shipped to one of the companies that buy old steel—steel mills, iron and steel foundries, scrap dealers, and detinners. Detinners remove the layer of tin from old steel cans. This tin is valuable and can be sold.

Steel can recycling follows almost the same process as aluminum can recycling. Steel cans, along with other steel scrap, are melted in a furnace and then poured into casters that continuously roll and flatten the steel into sheets. Recycled steel cans can be made into new cars, girders for buildings, or new food cans. In the U.S., steel cans and other steel products contain at least 25 percent recycled steel, with some containing nearly 100 percent recycled steel.

Like aluminum, steel can also be recycled again and again. It does not lose any of its strength or quality in the recycling process. It can be a never-ending process that continues to save energy and resources.